Litcius/Paper detail

Investigation of laser-induced bubble dynamics in water at high hydrostatic pressures

Ding Li, Ziwen Jia, Ye Tian, Ying Li, Yuan Lu, Wangquan Ye, Jinjia Guo, Ronger Zheng

2021Optics Express21 citationsDOIOpen Access PDF

Abstract

Hydrostatic pressure is a key factor that influences laser-induced bubble dynamics in water. In this work, we investigated laser-induced bubble dynamics at high hydrostatic pressures up to 53.2 MPa, by using a high-pressure chamber combined with the shadowgraph imaging technique. It was shown that at the atmosphere pressure, the bubble evolution agrees well with the Keller-Miksis model during the free expansion and collapse phase. As the ambient pressure increases, both the size and the oscillation period of the bubble decreases dramatically as a consequence of faster dynamics. The maximum bubble radius, as well as the collapse time, decrease nonlinearly with the increasing pressure; while the pressurization effect on bubble expansion before 100 ns is negligible due to the high internal bubble pressure in the early stage. Time-resolved plasma emission images were also taken with an ICCD camera to illustrate the plasma evolution at high hydrostatic pressures. It was demonstrated that at a high pressure above 40 MPa, the plasma can gain energy from the bubble collapse, while the bubble will lose its energy, which may lead to a shorter collapse time than that obtained from the numerical calculation. This work provides insight into laser-induced bubble dynamics and the plasma-bubble interaction at high hydrostatic pressures.

Topics & Concepts

BubbleShadowgraphMaximum bubble pressure methodHydrostatic pressureRADIUSMechanicsLaserMaterials scienceOpticsHydrostatic equilibriumLiquid bubbleCavitationPlasmaPhysicsNuclear physicsComputer scienceQuantum mechanicsComputer securityLaser-induced spectroscopy and plasmaLaser-Ablation Synthesis of NanoparticlesUltrasound and Cavitation Phenomena